FR2735922A1 - CHARGING PUMP TYPE NEGATIVE VOLTAGE CIRCUIT - Google Patents

Abstract

The invention relates to a charge pump type negative voltage generator circuit, made from a P-type substrate, and supplying a negative voltage (VN) at an output (2 ') by pumping negative charges in n cells. pumping cells (C'1 to C'n) connected in series, n being an integer, these pumping cells comprising P-type transistors whose wells are connected to a node (15) in order to be positively biased. The circuit comprises switching means (18, 19) for selectively supplying on the node (15) a bias voltage (VB) of the wells greater than or equal to the potential present at the output as long as this potential is greater than a positive reference voltage (REF), and to supply a lower well bias voltage (Vread) when the potential present at the output is lower than said reference voltage. This prevents the appearance of latchup phenomena in the transistors of the pump cells.

Description

Voltage generator circuit

charge pump type negative.

  The invention relates to a circuit for generating

  charge pump type negative voltage.

  We are currently seeing the development in integrated circuits of the use of negative high voltage generator circuits of the charge pump type. Thus, for example, US Pat. No. 5,077,691 describes such a pump and its application for programming a

Flash type EEPROM memory.

  FIG. 1 schematically illustrates a known pump structure, produced in MOS technology from a P-type substrate. It comprises a set of n (n whole number) elementary cells Ci to Cn, the structure of which is illustrated in FIG. 2. These cells are connected in series between an input 1 and an output 2. The purpose of such a circuit is conventionally to supply a circuit of the capacitive type, shown diagrammatically in FIG. 1 by a capacitor 3, with a negative voltage VN produced at from a positive supply voltage VCC and a reference or ground voltage. These cells receive control signals A, B, C, D (illustrated in timing diagrams 3a to 3d) switching cyclically between 0

volts (ground) and VCC.

  An elementary cell, illustrated in FIG. 2, comprises: - an input 4 for receiving an IN voltage, - an output 5 for supplying an OUT voltage, and - two inputs 6 and 7 for receiving signals

CK1 and CK2.

  The cell illustrated in FIG. 2 comprises: - a first P-type transistor 8 whose source is connected to input 4 and whose drain is connected to output 5, - a second P-type transistor 9 whose drain is connected to input 4, the source of which is connected to the control gate of transistor 8, and the control gate of which is connected to output 5, - a third P-type transistor 10 mounted as a diode, the source and gate of which the control are connected to the input 4, and the drain of which is connected to the output 5, a first capacitor 11 of which a first pole is connected to the control gate of the transistor 8, and the second pole of which is connected to the 'input 6, - a second capacity 12, a first pole of which is connected to the output 5, and the second pole of which is connected to

entry 7.

  In practice, the capacitors 11 and 12 are produced using P-type transistors, the first pole of these capacitors corresponding to a control gate and the second pole corresponding to a drain and a source.

interconnected.

  The signals CK1 and CK2 will either be respectively the signals A and B illustrated in FIGS. 3a and 3b, or the

  signals C and D illustrated in FIGS. 3d and 3c.

  Assuming that the signals A and C are initially at 0 and that the signals B and D are initially at VCC, the signals A, B, C and D are such that: - the rise at VCC of the signal A causes the descent to 0 of signal B, the descent to 0 of signal B causes signal D to rise to VCC, - the rise to VCC of signal D causes signal C to descend to 0, this signal C rising to VCC after a certain delay, - the ascent to VCC of signal C causes signal D to go down to 0, - the descent of signal D causes signal B to rise to VCC, - the rise to signal B of VCC causes signal A to go down to 0, this signal A dating back to

VCC and so on.

  In a cell, the negative charges are transferred from the input 4 on the falling edge of the signal CK1 (ie from A or from C), the transistor 8 then being on. On the rising edge of this signal CK1 the transistor 8 is blocked. On falling edge of signal CK2 (i.e. from B or D), the output voltage OUT

increases in absolute VCC.

  Consecutive cells receiving signals of opposite polarities on their inputs 6 and 7, they are successively connected two by two. Each cell is alternately connected to the one that succeeds it and the one that precedes it. The input of the first cell Ci is connected to input 1, the latter being connected to ground. We gradually transfer the negative charges from one cell to another and the negative output voltage VN (voltage present at the output of the last cell Cn) goes

  gradually grow in absolute value.

  As has been said, the pump is produced on a P-type substrate. Conventionally, the wells of the P-type transistors are therefore positively polarized to ensure that they can be conducting. This polarization is achieved for example by connecting the boxes to a common conductive line produced on a

  metallization layer of the MOS circuit.

  We generally limit the potential of the boxes,

  noted VB. This avoids creating grid-

  box too large, and therefore not to risk destroying the PMOS transistors. On the other hand, it is preferable to limit the potential of the boxes if significant negative voltages are produced, for example from - 10 to - 15 volts. Too large a potential difference between the wells and the active areas of the transistors of the pumping cells risks causing destruction of these transistors if it reaches the breakdown voltage of these transistors. Finally, limiting the potential of the boxes makes it possible to limit the losses in the transistors due to the substrate effect. This limitation of the substrate effect makes it possible to produce a more compact pump, the number of cells necessary to produce a voltage of given value being all the less important as the losses in these transistors are low. Furthermore, the existence of commutations in the transistors 8 of the pumping cells is conditioned by the fact that the supply voltage is greater than the losses, expressed in absolute value, in these transistors. The limitation of the substrate effect therefore makes it possible to produce a pump which operates for supply voltage values.

weaker.

  Limiting the potential VB does not pose any problem as long as the capacitive circuit supplied at the pump output is connected only to this pump. However, in circuits such as that described for example in US Pat. No. 577,691, the capacitive circuit in question is formed by grids of storage transistors which can also be connected to supply circuits producing positive voltages. As a result, it may be that when the output 2 of the pump is connected to the capacitive circuit 3, the latter is positively charged at a voltage VP. During a transient phase, the positive charges will be discharged through the cells Cn to Ci of the pump, from its output 2 to its input 1. If the voltage VP is greater than the desired bias voltage VB of the cells of the cell transistors of the pump, there is a risk of seeing an unlocking phenomenon (or latchup in English) appear by creation of parasitic PNP transistors between the substrate and the active areas of the P-type transistors of the cells. One solution is to polarize the boxes so that this risk of latchup is eliminated, that is to say concretely to choose VB such that VB is always greater than VP. Compared to a pump not supplying a capacitive circuit which can be positively charged, there is a risk, in order to avoid the risk of latchup, of having to increase the number of cells of the pump (the substrate effect being greater in the pump cell transistors) or to limit the value of the voltage produced by the pump (to avoid a risk of breakdown

transistors).

  An object of the invention is to propose a pump structure which makes it possible to limit the polarization potential of the boxes, while not presenting any

risk of latchup.

  Thus, the invention relates to a negative voltage generator circuit of the charge pump type, produced from a P type substrate and supplying an output with a negative voltage by pumping negative charges in n pump cells connected in series. , n being an integer, these pumping cells comprising P-type transistors whose wells are connected to a node to be positively biased, characterized in that it comprises switching means for selectively supplying a voltage of polarization of the boxes greater than or equal to the potential present at the output as long as this potential is greater than a positive reference voltage, and to provide a lower voltage of polarization of the boxes when the potential present at the output is

  lower than said reference voltage.

  Other features and advantages will appear

  reading the following description, to read

  together with the accompanying drawings in which: - Figure 1 schematically shows a negative charge pump according to the state of the art, - Figure 2 shows a detailed diagram of a basic cell of the pump of Figure 1, - Figures 3a to 3d show timing diagrams of control signals of the pump of the figure of Figure 1, - Figure 4 schematically shows a pump

according to the invention.

  FIG. 1 schematically illustrates a known pump structure, produced in MOS technology from a P-type substrate. It comprises a set of n (n whole number) elementary pumping cells Ci to Cn, the structure of which is illustrated in FIG. 2. These cells are connected in series between an input 1 and an output 2. The purpose of such a circuit is conventionally to supply a capacitive type circuit, shown diagrammatically in FIG. 1 by a capacitor 3, with a negative voltage VN produced from a positive supply voltage VCC and a reference or ground voltage. These cells receive control signals A, B, C, D (illustrated in timing diagrams 3a to 3d) switching

  cyclically between 0 volts (ground) and VCC.

  An elementary cell, illustrated in FIG. 2, comprises an input 4 for receiving an IN voltage, an output 5 for supplying an OUT voltage, and two inputs 6

  and 7 for receiving clock signals CK1 and CK2.

  The cell illustrated in FIG. 2 comprises a first P-type transistor 8 whose source is connected to input 4 and whose drain is connected to output 5. It includes a second P-type transistor 9 whose drain is connected to l input 4, the source of which is connected to the control gate of transistor 8, and the control gate of which is connected to output 5. The cell also comprises a third P-type transistor 10 mounted as a diode, the source and the control gate are connected to the input 4, and the drain of which is connected to the output 5. It also includes a first capacitor 11, a first pole of which is connected to the control gate of the transistor 8, and the second pole of which is connected to input 6, and a second capacity 12, a first pole of which is connected to output 5, and of which the second pole

is connected to input 7.

  In practice, the capacitors 11 and 12 are produced using P-type transistors, the first pole of these capacitors corresponding to a control gate and the second pole corresponding to a drain and a source.

interconnected.

  The signals CK1 and CK2 will either be respectively the signals A and B illustrated in FIGS. 3a and 3b, or the

  signals C and D illustrated in FIGS. 3d and 3c.

  Assuming that the signals A and C are initially at 0 and that the signals B and D are initially at VCC, the signals A, B, C and D are such that: - the rise at VCC of the signal A causes the descent to 0 of signal B, the descent of signal B causes the rise to VCC of signal D, - the rise to VCC of signal D causes the descent of signal C to 0, this signal C rising to VCC after a certain delay, - the rise to VCC of signal C causes signal D to go down to 0, - the descent to 0 of signal D causes signal B to rise at VCC, - the rise to VCC of signal B causes signal A to go down to 0, this signal A dating back to

VCC and so on.

  In a cell, the negative charges are transferred from the input 4 on the falling edge of the signal CK1 (ie from A or from C), the transistor 8 then being on. On the rising edge of this signal CK1 the transistor 8 is blocked. On falling edge of signal CK2 (i.e. from B or D), the output voltage OUT

increases in absolute VCC.

  Consecutive cells receiving signals of opposite polarities on their inputs 6 and 7, they are successively connected two by two. Each cell is alternately connected to the one that succeeds it and the one that precedes it. The input of the first cell C1 is connected to the input 1 of the pump, this input 1 being connected to ground. We gradually transfer the negative charges from one cell to another and the negative output voltage VN, supplied at the output of the last

  cell Cn, will gradually increase in absolute value.

  FIG. 4 schematically represents a charge pump produced in accordance with the invention. Its structure is identical to that of FIG. 1, but it includes an additional circuit 13. The charge pump illustrated in FIG. 4 comprises a set of n (n whole number) elementary pumping cells C'l to C'n, the structure is illustrated in Figure 2. These cells are mounted in series between an inlet 1 'and an outlet 2'. The pump supplies a capacitive type circuit, represented in FIG. 4 by a capacity 3 ′, with a negative voltage VN produced from a positive supply voltage VCC and a reference or ground voltage. These cells receive control signals A, B, C, D (illustrated in timing diagrams 3a to 3d)

  cyclically switching between 0 volts (ground) and VCC.

  The boxes of the P-type transistors of cells C'1 to C'n are connected by conductive means not shown (for example a conductive line produced on a metal layer of the circuit) to a node 15 to receive a positive potential of box VB . Knot 15

  corresponds to an output of circuit 13.

  Preferably, the circuit 13 comprises a comparator 16 for comparing a voltage V, received on an input 14 of the circuit 13, with a reference voltage REF. This reference voltage REF will preferably be produced by a circuit 17 of the bandgap type (not described in detail, this type of circuit being well known to those skilled in the art), which makes it possible to produce a reference voltage stable in temperature and independent of the supply voltage VCC (as long as the voltage REF at

  produce is less than VCC, of course).

  The output of comparator 16 is connected to MOS switches 18 and 19 in order to selectively connect node 15 either to a first terminal 20 or to a second terminal 21, these two terminals providing

  positive voltages of different values.

  Suppose that the capacitive circuit 3 'can receive either the voltage VN produced by the pump, or a positive voltage VP present on a terminal 22. It may be that when the output 2' of the pump is connected to the capacitive circuit 3 ', this is positively charged at the voltage VP. We then have VN = VP (considering that VN is the voltage present on the output 2 '). During a transient phase, the positive charges will be discharged through the cells C'n to C'l of the pump, from its output 2 'to the ground to which the input 1' is connected. If the voltage VP is greater than the bias voltage VB of the boxes of the transistors of the cells C'1 to C'n of the pump, there is a risk of seeing an unlocking phenomenon appear (or latchup in English) by creation of parasitic PNP transistors between the substrate and the active areas of the P-type transistors of the cells. In order to prevent this phenomenon from appearing, the node 15 is then connected, to which the boxes of the transistors P of the cells are connected, to terminal 20, the latter

  providing a voltage greater than or equal to VP.

  The switch 18 is then closed and the switch 19 is open. For example, if VP is less than or equal to VCC, terminal 20 supplies the voltage VCC. The comparator 16 will be supplied between ground and the VCC voltage. The voltage VP may very well be greater than VCC. In this case, comparator 16 will be supplied accordingly and terminal 20 will supply a voltage greater than VCC. We

  for example, connect terminal 20 to terminal 22.

  As we have seen, it is preferable to limit the value of the voltage VB to a given positive value in order not to create an excessively large grid-box field in the transistors, which risks destroying them, rendering the pump inoperative. For example, we will choose to have VB = Vread = 2.2 volts, with VCC = 5 volts, the

  voltage Vread being the voltage supplied by terminal 21.

  As long as the voltage V received by the comparator 16 is greater than the potential Vread, the node 15 is connected to the terminal 20. Once the voltage V is equal to or less than Vread, the node 15 is connected to the terminal 21. The switch 19 is then closed and the switch 18 is open. We will choose REF 5 Vread (for example REF = 1.8 volts). The voltage V taken will preferably be the voltage present at the output of the first cell C'li of the pump in order to be sure that there is no risk of occurrence of latchup phenomenon in any of the n cells of the pump. . 1l

Claims (4)

  1 - Negative voltage generator circuit of the charge pump type, produced from a P type substrate and supplying an output (2 ') with a negative voltage (VN) by pumping negative charges into n pumping cells ( C'l to C'n) connected in series, n being an integer, these pumping cells comprising P-type transistors whose wells are connected to a node (15) to be positively polarized, characterized in that comprises switching means (18, 19) for selectively supplying on the node (15) a voltage (VB) of polarization of the wells greater than or equal to the potential present at the output as long as this potential is greater than a positive reference voltage (REF ), and to provide a lower bias voltage of the wells (Vread) when the potential present at the output is less than said reference voltage.   2 - Circuit according to claim 1, characterized in that the switching means comprise MOS type switches (18, 19) for selectively connecting the node (15) to terminals (20, 21) providing positive voltages of different values , so that the node (15) is connected to a only terminals at a time.   3 - Circuit according to claim 2, characterized in that it comprises a comparator (16) having a first input connected to an output of one of the pumping cells, a second input receiving the reference voltage (REF), and a output to order the switches (18, 19).   4 - Circuit according to claim 3, characterized in that the first input of the comparator (16) is connected to the output of the first pumping cell (C'1i).